Transparent conducting oxides

ABSTRACT

The invention provides a transparent conducting film which comprises a compound of formula (I): Zn 1-x [M] x O 1-y [X] y (I) wherein: x is greater than 0 and less than or equal to 0.25; y is from 0 to 0.1; [X] is at least one dopant element which is a halogen; and [M] is: (a) a dopant element which is selected from: a group 14 element other than carbon; a lanthanide element which has an oxidation state of +4; and a transition metal which has an oxidation state of +4 and which is other than Ti or Zr; or (b) a combination of two or more different dopant elements, at least one of which is selected from: a group 14 element other than carbon; a lanthanide element which has an oxidation state of +4; and a transition metal which has an oxidation state of +4 and which is other than Ti or Zr. The invention further provides coatings comprising the films of the invention, processes for producing such films and coatings, and various uses of the films and coatings.

FIELD OF THE INVENTION

The invention relates to transparent conducting films, to coatings comprising such films, to processes for producing such films and coatings, and to various uses of the films and coatings.

BACKGROUND TO THE INVENTION

Sn-doped In₂O₃ thin films [In_(2-x)Sn_(x)O₃: ITO] exhibit a remarkable combination of optical and electrical transport properties. These include a low electrical resistivity, which is typically in the order of 10⁻⁴ Ωcm. This property is related to the presence of shallow donor or impurity states located close to the host (In₂O₃) conduction band, which are produced by chemical doping of Sn⁺⁴ for In⁺³ or by the presence of oxygen vacancy impurity states in In₂O_(3-x). The films also exhibit high optical transparency (>80%) in the visible range of the spectrum (P. P. Edwards, et al.; Dalton Trans., 2004, 2995-3002).

Transparent conductive coatings or layers which comprise ITO have many applications, including in liquid crystal displays, flat panel displays (FPDs), plasma displays, touch panels, electronic ink applications, organic light-emitting diodes, electroluminescent devices, optoelectronic devices, photovoltaic devices, solar cells, photodiodes, and as antistatic coatings or EMI shieldings. ITO is also used for various optical coatings, most notably infrared-reflecting coatings (hot mirrors) for architectural, automotive, and sodium vapor lamp glasses. Other uses include gas sensors, antireflection coatings, electrowetting on dielectrics, and Bragg reflectors for VCSEL lasers. Furthermore, ITO can be used in thin film strain gauges. ITO thin film strain gauges can operate at temperatures up to 1400° C. and can be used in harsh environments.

Due to the cost and scarcity of indium metal, the principle component of ITO, a stable supply of indium may be difficult to sustain for an expanding market for flat panel displays, solar cells and other applications. There is therefore an ongoing need to reduce the amount of indium or produce indium-free phases as alternative transparent conducting materials for transparent conductor applications.

SUMMARY OF THE INVENTION

The present inventors have provided transparent conducting films of doped zinc oxides that have temperature-stable electrical and optical properties which are comparable to those of ITO. The doped zinc oxide films are attractive for transparent conductor applications as they are easy to produce from inexpensive, abundant precursors, and are non-toxic. Furthermore, zinc oxide has a higher visible transmittance than many other conductive oxide films and is more resistant to reduction by hydrogen-containing plasma processes that are commonly used for the production of solar cells. Zinc oxide itself is also inexpensive, abundant in nature and non-toxic. It also has certain properties which are considered important for transparent conductors, such as a band gap of 3.4 eV, an intrinsic carrier concentration of about 10⁶ cm⁻³ and an electron Hall mobility of 200 cm²V⁻¹s⁻¹.

Accordingly, the present invention provides a transparent conducting film which comprises a compound of formula (I):

Zn_(1-x)[M]_(x)O_(1-y)[X]_(y)  (I)

wherein:

x is greater than 0 and less than or equal to 0.25;

y is from 0 to 0.1;

[X] is at least one dopant element which is a halogen; and

[M] is:

-   -   (a) a dopant element which is selected from: a group 14 element         other than carbon; a lanthanide element which has an oxidation         state of +4; and a transition metal which has an oxidation state         of +4 and which is other than Ti or Zr; or     -   (b) a combination of two or more different dopant elements, at         least one of which is selected from: a group 14 element other         than carbon; a lanthanide element which has an oxidation state         of +4; and a transition metal which has an oxidation state of +4         and which is other than Ti or Zr.

The invention further provides a process for producing a transparent conducting film, which film comprises a compound of formula (I):

Zn_(1-x)[M]_(x)O_(1-y)[X]_(y)  (I)

wherein:

x is greater than 0 and less than or equal to 0.25;

y is from 0 to 0.1;

[X] is at least one dopant element which is a halogen; and

[M] is:

-   -   (a) a dopant element which is selected from: a group 14 element         other than carbon; a lanthanide element which has an oxidation         state of +4; and a transition metal which has an oxidation state         of +4 and which is other than Ti or Zr; or     -   (b) a combination of two or more different dopant elements, at         least one of which is selected from: a group 14 element other         than carbon; a lanthanide element which has an oxidation state         of +4; and a transition metal which has an oxidation state of +4         and which is other than Ti or Zr;         which process comprises producing said film by pulsed laser         deposition.

Typically, the process further comprises:

-   -   (a) providing a target material in a chamber, which target         material comprises the elements Zn, O, [M] and optionally [X],         wherein [M] and [X] are as defined above;     -   (b) providing a substrate in the chamber;     -   (c) focusing a pulsed laser beam on the target material to         generate a plasma; and     -   (d) depositing the plasma on the substrate to form the film.

The pulsed laser deposition (PLD) process of the invention is particularly suitable for producing films, coatings and layers for transparent conductor applications because the composition of the grown film is close to that of the target, even for a multicomponent target. This provides control over the film's composition. PLD-produced films may also crystallize at lower deposition temperatures relative to other physical vapour deposition techniques due to the high kinetic energies of the ionized and ejected species in the laser plumes.

The invention further provides:

-   -   a transparent conducting film which is obtainable by the process         of the invention;     -   a transparent conducting coating which comprises a transparent         conducting film of the invention;     -   an organic light-emitting device, an electroluminescent device,         a solid-state light, a photovoltaic device, a solar cell, a         photodiode, a transparent electronic device, an electrode, a         display, a touch panel, a sensor, a window, flooring material, a         minor, a lense, a Bragg reflector, a strain gauge or a         radio-frequency identification (RFID) tag which comprises a         transparent conducting coating of the invention or a transparent         conducting film of the invention; and     -   glass or a polymer which is coated with the transparent         conducting coating of the invention.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a schematic illustration of the pulsed laser deposition apparatus.

FIG. 2 is a graph of film resistivity, ρ (left hand y axis), in units of Ωcm, versus SiO₂ content in the Si—ZnO target (x axis), in units of weight %; data points are shown as hollow squares. The graph also shows carrier concentration, η, (right hand y axis) in units of cm⁻³ versus the SiO₂ content in the Si—ZnO target (x axis) in units of weight %; data points are shown as solid circles.

FIG. 3 shows X-ray diffraction spectra (intensity on the y axis versus 2θ, in units of degrees, on the x axis) of an undoped ZnO film (bottom line) and Si-doped ZnO films prepared using 1 weight % (second line from bottom), 2 weight % (second line from top) and 3 weight % (uppermost line) SiO₂ content in the Si—ZnO target. Each of the films was deposited at 350° C. on borosilicate glass substrate.

FIG. 4 shows X-ray diffraction spectra (intensity on the y axis versus 2θ, in units of degrees, on the x axis) of bulk undoped ZnO (bottom line) and bulk Si—ZnO prepared using 1 weight % (second line from bottom), 2 weight % (second line from top) and 3 weight % (uppermost line) of SiO₂.

FIG. 5 shows an atomic force microscopy (AFM) image (2 μm×2 μm) of a Si-doped ZnO film prepared by pulsed laser deposition on borosilicate glass substrate. Grain growth is shown to occur in a direction perpendicular to the substrate surface. The root mean square (RMS) surface roughness is 3.2 nm.

FIG. 6 shows an atomic force microscopy (AFM) image (2 μm×2 μm) of an undoped ZnO film prepared by pulsed laser deposition on borosilicate glass substrate. Grain growth is shown to occur in a direction perpendicular to the substrate surface. The RMS surface roughness is 2.62 nm.

FIG. 7 shows X-ray diffraction spectra (intensity on the y axis, versus 20, in units of degrees, on the x axis) of Si-doped ZnO (“SiO₂—ZnO”) containing 5 weight % SiO₂, prepared using the solution phase synthesis method of Example 2. The spectra were recorded, respectively, at sample temperatures of 300° C. (bottom spectrum), 400° C., 500° C., 600° C., 700° C., 800° C. and 900° C. (top spectrum).

FIG. 8 shows X-ray diffraction spectra (intensity on the y axis, versus 20, in units of degrees, on the x axis) of Si-doped ZnO (“SiO₂—ZnO”) containing 10 weight % SiO₂, prepared using the solution phase synthesis method of Example 2. The spectra were recorded, respectively, at sample temperatures of 350° C. (bottom spectrum), 450° C., 550° C., 650° C., 750° C. and 850° C. (top spectrum).

DETAILED DESCRIPTION OF THE INVENTION

The films of the invention are both transparent and conducting. The word “transparent” as used herein means that the film has optical transmittance in the visible range of the spectrum, from about 400 nm to about 800 nm.

Usually, the film of the invention has a mean optical transparency in the visible range of the spectrum which is equal to or greater than about 50%. More typically, the mean optical transparency is equal to or greater than about 70%, or equal to or greater than about 75%. Even more typically, the mean optical transparency in the visible range of the spectrum is equal to or greater than about 80%. In one embodiment, the transparency of the film is optimised to a value equal to or greater than about 90%.

The word “conducting” as used herein means that the film is electrically conductive.

Pure zinc oxide films usually exhibit low conductivity (high resistivity) due to low carrier concentration. In order to decrease the electrical resistivity (increase electrical conductivity) it is necessary to increase either the carrier concentration or the carrier mobility in zinc oxide. The former may be achieved through either oxygen and/or zinc non-stoichiometry or doping with an impurity. Non-stoichiometric films have excellent electrical and optical properties, but they are not very stable at high temperatures. The films of the invention are therefore doped with at least one dopant element, [M]; the films of the invention have an electrical resistivity which is less than that of a pure, undoped, stoichiometric zinc oxide film, i.e. less than about 2.0×10⁻² Ωcm.

Usually, the film of the invention has an electrical resistivity, p, of less than or equal to about 1.0×10⁻² Ωcm. More typically, the film has an electrical resistivity of less than or equal to about 5.0×10⁻³ Ωcm, less than or equal to about 4.0×10⁻³ Ωcm or less than or equal to about 3.0×10⁻³ Ωcm. Even more typically, the film has an electrical resistivity of less than or equal to about 2.0×10⁻³ Ωcm.

In one embodiment, the film has an electrical resistivity of less than or equal to about 1.0×10⁻³ Ωcm. More typically, in this embodiment, the electrical resistivity is less than or equal to about 8.0×10⁻⁴ Ωcm, less than or equal to about 6.0×10⁻⁴ Ωcm, or less than or equal to about 5.0×10⁻⁴ Ωcm.

The film of the invention must be a thin film in order to provide transparency. Typically, the thickness of the film is selected to achieve an optimum balance between conductivity and transparency. Accordingly, the films of the invention usually have a thickness, d, of from about 100 Å (10 nm) to about 1 mm. More typically, the thickness, d, is from about 100 nm to about 100 μm. Even more typically, the thickness is from about 100 nm to about 1 μm or, for instance, from about 200 nm to about 500 nm In one embodiment, the thickness is about 4000 Å (400 nm). In another embodiment, the thickness is about 3000 Å (300 nm).

The film of the invention is doped with at least one dopant element, [M]. This usually increases the carrier concentration, η, in the zinc oxide, without seriously reducing the Hall carrier mobility, p, thereby decreasing the electrical resistivity of the film. The carrier concentration; η, in the film of the invention is typically greater than that of a pure, undoped, stoichiometric zinc oxide film. Thus, typically, the carrier concentration, η, in the film of the invention is greater than about 1×10¹⁹ cm⁻³. More typically, the carrier concentration, η, is equal to or greater than about 8×10¹⁹ cm⁻³ or, for instance, equal to or greater than about 1×10²⁰ cm⁻³. Even more typically, η is equal to or greater than about 2×10²⁰ cm⁻³. In one embodiment, it is equal to or greater than about 3×10²⁰ cm⁻³, for instance equal to or greater than about 5×10²⁰ cm⁻³, or equal to or greater than about 6×10²⁰ cm⁻³.

Typically, the Hall mobility, μ, is equal to or greater than about 10 cm²V⁻¹s⁻¹. More typically, μ is equal to or greater than about 15 cm²V⁻¹s⁻¹.

In the films of the invention, the dopant, [M], may be a single dopant element selected from a group 14 element other than carbon; a lanthanide element which has an oxidation state of +4; and a transition metal which has an oxidation state of +4 and which is other than Ti or Zr. Alternatively, [M] may be a combination of two or more different dopant elements, in any relative proportion such that the total amount of dopant atoms, x, is still greater than 0 and less than or equal to 0.1. In the latter case, where [M] is a combination of two or more different dopant elements, at least one of said two or more elements is selected from a group 14 element other than carbon; a lanthanide element which has an oxidation state of +4; and a transition metal which has an oxidation state of +4 and which is other than Ti or Zr.

In one embodiment, where [M] is a combination of two or more different dopant elements, none of said two or more elements is Ga and at least one of said two or more elements is selected from a group 14 element other than carbon; a lanthanide element which has an oxidation state of +4; and a transition metal which has an oxidation state of +4 and which is other than Ti or Zr.

In another embodiment, where [M] is a combination of two or more different dopant elements, none of said two or more elements is a group 13 element and at least one of said two or more elements is selected from a group 14 element other than carbon; a lanthanide element which has an oxidation state of +4; and a transition metal which has an oxidation state of +4 and which is other than Ti or Zr.

In one embodiment, the transparent conducting film does not contain Ga. In another embodiment, the transparent conducting film does not contain any group 13 element.

In one embodiment, [M] is a combination of two or more different dopant elements, wherein:

at least one of said two or more different elements is selected from a group 14 element other than carbon; a lanthanide element which has an oxidation state of +4; and a transition metal which has an oxidation state of +4 and which is other than Ti or Zr; and

at least one of said two or more different elements is selected from an alkali metal, an alkaline earth metal, a transition metal other than zinc, a p-block element, a lanthanide element or an actinide element. Typically, the p-block element is other than Ga. More typically, the p-block element is other than a group 13 element (i.e. it is other than B, Al, Ga, In and Tl).

In this embodiment, the alkali metal is typically selected from Li, Na, K, Rb and Cs. Typically, the alkaline earth metal is selected from Be, Mg, Ca, Sr and Ba. Usually, the transition metal other than zinc is selected from Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Y, Zr, Nb, Mo, Tc, Ru, Rh, Pd, Ag, Cd, La, Hf, Ta, W, Re, Os, Ir, Pt, Au and Hg. More typically, the transition metal other than zinc is selected from Sc, Ti, Y, Zr, La and Hf. Typically, the p-block element is selected from B, Al, Ga, In, Tl, P, As, Sb, Bi, S, Se, Te and Po. In one embodiment, the p-block element is selected from B, Al, In, Tl, P, As, Sb, Bi, S, Se, Te and Po. In another embodiment, the p-block element is selected from P, As, Sb, Bi, S, Se, Te and Po.

In one embodiment, [M] is a combination of (i) an element selected from a group 14 element other than carbon; a lanthanide element which has an oxidation state of +4; and a transition metal which has an oxidation state of +4 and which is other than Ti or Zr; and (ii) a transition metal, p-block or lanthanide element which has an oxidation state of +3. The element which has an oxidation state of +3 may, for instance, be Al, Ga, In or Sc. In one embodiment, however, the element which has an oxidation state of +3 is other than Ga. In another embodiment, the element which has an oxidation state of +3 is other than a group 13 element.

Typically, the dopant [M] is a single dopant element selected from a group 14 element other than carbon; a lanthanide element which has an oxidation state of +4; and a transition metal which has an oxidation state of +4 and which is other than Ti or Zr.

The group 14 elements other than carbon are Si, Ge, Sn and Pb. Thus, typically, [M] is, or comprises, an element selected from Si, Ge, Sn and Pb. More typically, [M] is, or comprises, Si. Thus, [M] is typically a single dopant element which is Si, Ge, Sn or Pb; or a combination of two or more different dopant elements, one of which is Si, Ge, Sn or Pb. [M] is more typically a single dopant element which is Si; or a combination of two or more different dopant elements, one of which is Si.

Most typically, [M] is a single dopant element which is Si.

In the film of the invention the at least one dopant element which is a halogen, [X], may be a single halogen element. Thus, [X] may, for instance, be F or Cl. Typically [X] is F. Alternatively, [X] may be a combination of two or more different halogens, in any relative proportion such that the total amount of dopant halogen atoms, y, is still from 0 to 0.1. [X] may, for instance, be a combination of F and another halogen, for instance Cl. Typically, however, [X], when present, is a single halogen element which is F.

Accordingly, in one embodiment, the compound of the film of the invention is a compound of formula (II):

Zn_(1-x)[M]_(x)O_(1-y)F_(y)  (II)

wherein x and [M] are as defined above and y is greater than 0 and less than or equal to 0.1.

In another embodiment, y is 0 and the compound of the film of the invention is a compound of formula (III):

Zn_(1-x)[M]_(x)O  (III)

wherein x and [M] are as defined above.

Typically, [M] is a single dopant element which is Si and y is 0.

Accordingly, in one embodiment the film comprises a compound of formula (IV):

Zn_(1-x)Si_(x)O  (IV)

wherein x is as defined above.

The term “lanthanide element which has an oxidation state of +4”, as used herein, means any lanthanide element which has a stable oxidation state of +4, irrespective of whether or not the element has one or more other stable oxidation states. Such elements include Ce, Pr, Nd, Tb and Dy. Accordingly, in the transparent conducting film of the invention, or in the process of the invention, [M] may be, or may comprise, an element selected from Ce, Pr, Nd, Tb and Dy. Typically, when [M] is a lanthanide, it is, or comprises, Ce.

The term “transition metal which has an oxidation state of +4”, as used herein, means any transition metal which has a stable oxidation state of +4, irrespective of whether or not the transition metal can exist in one or more other oxidation states. Many transition metals other than Ti and Zr have a stable oxidation state of +4. Such transition metals include Hf, V, Mn, Nb, Mo, Tc, Ru, Rh, Pd, Ta, W, Re, Os, Ir and Pt. Accordingly, [M] may be, or may comprise, an element selected from Hf, V, Mn, Nb, Mo, Tc, Ru, Rh, Pd, Ta, W, Re, Os, Ir and Pt.

The dopant [M] is, or comprises, an element which has an oxidation state of +4. Thus, as the dopant [M] is introduced into the zinc oxide, it is typically oxidised to [M⁴⁺], nominally replacing Zn²⁺, producing two electrons for each zinc atom replacement. This serves to increase the electron density (carrier concentration) in the sample and decrease resistivity. Typically, in practice, the resistivity decreases and reaches a minimum value as the amount of dopant is increased to an “optimum” concentration; then, if the dopant concentration is increased further, the resistivity increases again and the carrier concentration decreases. Without wishing to be bound by theory, it is thought that this decrease in carrier concentration and increase in resistivity beyond the “optimum” dopant concentration may be due to increased disorder of the crystal lattice, which causes phonon scattering and results in a decrease in the mobility and free carrier concentration. Alternatively, the increase in resistivity may be due to the dopant atoms forming neutral defects, which do not contribute free electrons, or to an increase in the concentration of electron traps as a result of excess doping. The maximum dopant concentration in the films of the invention is typically 25 atom % (based on the total number of Zn and dopant atoms). More typically, the dopant concentration is less than about 10 atom %, for instance, less than about 5 atom %. Even more typically, the dopant concentration is less than or equal to about 4 atom %. Even more typically, the dopant concentration is from about 1 to about 4 atom %, for instance from about 1.5 to about 3.5 atom %, or from about 2 to about 3 atom %. Accordingly, x, in the compound of formula 1, is greater than 0 and less than or equal to 0.25. Typically, x is greater than 0 and less than or equal to 0.1. More typically, x is greater than 0 and less than or equal to about 0.05; x may for instance be from about 0.01 to about 0.05, or from about 0.01 to about 0.04, for instance from about 0.015 to about 0.035, or from about 0.02 to about 0.03. In one embodiment x is from about 0.03 to about 0.05, for instance x is about 0.04. In another embodiment, x is about 0.03, for instance 0.027.

Typically, the crystal structure of the film of the invention (which may be studied by X-ray diffraction) is similar to that of an undoped ZnO film. The film of the invention is usually a polycrystalline film. More typically, it is a polycrystalline, c-axis-oriented film.

Usually, the root-mean-square (RMS) surface roughness of the film of the invention is less than that of a pure, undoped stoichiometric zinc oxide film. In one embodiment, the film has a root-mean-square surface roughness value which is equal to or less than 3.0 nm. The root-mean-square surface roughness of a film can be measured using atomic force microscopy (AFM).

Typically, the transparent conducting films of the invention are produced by pulsed laser deposition (PLD).

PLD is a powerful tool for growth of complex compound thin films. In conventional nanosecond PLD, a beam of pulsed laser light with a typical pulse duration of a few nanoseconds is focused on a solid target. Due to the high peak power density of the pulsed laser, the irradiated material is quickly heated to above its melting point, and the evaporated materials are ejected from the target surface into a vacuum in a form of plasma (also called a plume). For a compound target, the plume contains highly energetic and excited ions and neutral radicals of both the cations and the anions with a stoichiometric ratio similar to that of the target. This provides one of the most unique advantages of PLD over the conventional thin film growth techniques such as chemical vapor deposition (CVD) and molecular beam epitaxy (MBE). The PLD process of the invention is therefore advantageous because the composition of the grown film is close to that of the target, even for a multicomponent target, which provides additional control over the film's composition. PLD-produced films may also crystallize at lower deposition temperatures relative to other physical vapour deposition techniques (e.g. dc magnetron sputtering) due to the high kinetic energies of the ionized and ejected species in the laser plumes.

Typically, the process of the invention, for producing a transparent conducting film of the invention by PLD, comprises:

-   -   (a) providing a target material in a chamber, which target         material comprises the elements Zn, O, [M] and optionally [X],         wherein [M] and [X] are as defined above;     -   (b) providing a substrate in the chamber;     -   (c) focusing a pulsed laser beam on the target material to         generate a plasma; and     -   (d) depositing the plasma on the substrate to form the film.

Different dopant elements [M] and different halogen dopant elements [X] can be incorporated into the film by using a solid target material made of ZnO powder mixed with different impurity compounds. For instance, one can simply choose compounds that contain the desired dopant elements [M] and/or [X]. Typically, one chooses one or more oxides of the dopant element(s) [M]. Similarly, one or more halides can be chosen for introducing the dopant elements [X]. Furthermore, the dopant concentration can be controlled by varying the weight percentage of the dopant compound or compounds.

Typically, the molar ratio of Zn to [M] in the target is (1-x):x wherein x is greater than 0 and less than or equal to about 0.25. More typically, x is greater than 0 and less than or equal to about 0.1. Even more typically, x is greater than 0 and less than or equal to about 0.05, and more typically x is from about 0.01 to about 0.05, or from about 0.01 to about 0.04, for instance from about 0.015 to about 0.035, or from about 0.02 to about 0.03.

In one embodiment x is from about 0.03 to about 0.05, for instance about 0.04. In another embodiment x is about 0.03, for instance 0.027.

Typically, the molar ratio of 0 to [X] in the target is (1-y):y wherein y is from 0 to 0.1. In one embodiment, [X] is absent and y is 0. The target material is typically prepared by heating a mixture of zinc oxide and an oxide of [M]. Typically, the mixture is heated at a temperature which is from about 600° C. to about 1000° C. More typically, the mixture is heated at about 800° C.

When [M] is Si, the concentration of the oxide of [M], SiO₂, in the mixture of zinc oxide and SiO₂ is typically greater than about 0.5 weight %. More typically, the concentration of SiO₂ in the mixture is from about 1.0 weight % to about 5.0 weight %. Even more typically, the concentration of SiO₂ is from about 1.5 weight % to about 4.0 weight %, for instance about 2.0 weight %. The resistivity and carrier concentration of the resulting film are typically maximised when this concentration of SiO₂ is used in the target material.

Usually, the mixture of zinc oxide and the oxide of [M] is prepared by mixing zinc oxide powder and a powder of the oxide of [M] in a suitable solvent, for instance acetone. Typically, the mixture is heated at a temperature which is from about 600° C. to about 1000° C. More typically, the mixture is heated at about 800° C. Typically, the mixture is heated at the temperature for about 8 hours or longer, more typically for about 12 hours or longer.

After heating, the mixture is usually ground and then heated again, at a second temperature for a further period of time. Typically, the second temperature is from about 600° C. to about 1000° C., and is more typically about 700° C. The further period of time is usually about 4 hours or longer, more typically about 7 hours or longer.

After preparation of the target material as described above, the material is typically compacted to form the target. This may be done using a standard pellet press. The compacted target is then usually heated, to lend mechanical strength to the target. Typically, the compacted target is heated at a temperature which is from about 600° C. to about 1000° C., for instance at about 800° C. The compacted target is usually heated for about 4 hours or longer, more typically for about 7 hours or longer.

Accordingly, the target material typically comprises (i) a mixture of zinc oxide and an oxide of [M], and/or (ii) [M]-doped zinc oxide. In one embodiment, the target material comprises a mixture of (i) zinc oxide, (ii) an oxide of [M], and (iii) [M]-doped zinc oxide. The [M]-doped zinc oxide may be a compound of formula (I) in which y is 0.

Usually, the target material comprises an intimate mix of oxides, for instance an intimate mixture of zinc oxide, an oxide of [M] and/or [M]-doped zinc oxide. The intimate mix is important for even deposition. Without wishing to be bound by theory, it is thought that the high energy of the deposition process and the atom-by-atom growth of the film from the mixed atomic plasma are important for forming homogeneous films of the invention.

The inventors have devised a convenient solution-based process, exemplified below in Example 2, for producing an [M]-doped zinc oxide. The [M]-doped zinc oxide thus produced is typically a compound of formula (I) as defined above in which y is 0.

The solution-based process comprises:

-   -   (a1) heating a solution comprising a zinc compound and a         compound comprising [M], wherein [M] is as defined above;     -   (a2) performing a solvent removal step; and     -   (a3) heating the resulting solid to produce said [M]-doped zinc         oxide.

This solution-based process can be used to produce the target material used in step (a) of the process of the invention for producing a transparent conducting film by PLD. It can also be used to produce suitable target materials for other processes for producing the transparent conductive films of the invention, e.g. physical vapour deposition techniques such as dc magnetron sputtering.

Accordingly, in one embodiment, the target material used in step (a) of the process of the invention for producing a transparent conducting film by PLD, is produced by:

-   -   (a1) heating a solution comprising a zinc compound and a         compound comprising [M];     -   (a2) performing a solvent removal step; and     -   (a3) heating the resulting solid to produce said target         material.

This solution-based process for producing the target material can advantageously be carried out at a relatively low temperature. Typically, the temperature of said heating in step (a1) does not exceed 200° C. Typically, the temperature of said heating in step (a3) does not exceed 500° C.

Any suitable zinc compound may be used, as can any suitable compound comprising [M]. The zinc compound is typically a zinc salt. The zinc compound is usually soluble in the solvent or mixture of solvents employed in the reaction. Typically, the zinc compound is zinc citrate. The compound comprising [M] is typically a salt of [M]. Again, the compound comprising [M] is typically soluble in the solvent or mixture of solvents employed. Typically, [M] is Si and the compound comprising [M] is a silicon salt, for instance silicon tetra-acetate.

Any suitable solvent or mixture of solvents may be employed. Typically, the solvent comprises water and/or an alcohol. More typically, the solvent comprises a water and a polar organic solvent, for instance ethylene glycol.

In one embodiment, the zinc compound is zinc citrate and the compound comprising [M] is silicon tetra-acetate. Typically, in this embodiment, step (a1) comprises treating a solution of zinc citrate with a solution of silicon tetra-acetate in the presence of heat. Typically, the zinc citrate solution is an aqueous or alcoholic solution, more typically an aqueous solution. The solvent used for the solution of silicon tetra-acetate may be a polar organic solvent, for instance ethylene glycol. Usually, the temperature at which the solution of zinc citrate is treated with the solution of silicon tetra-acetate is from 70 to 150° C., more typically, from 80 to 120° C. This heating is typically carried out for from 0.5 to 4 hours, more typically for about 2 hours. Typically, the resulting solution is then heated at a higher temperature of from 110 to 150° C., typically at about 130° C. Usually, a clear to yellow solution is then formed. Then, subsequently, the reaction mixture is typically heated at a second period of time (for instance about 5 to 20 hours, more typically about 14 hours) at a still higher temperature, for instance at a temperature of from 150 to 200° C., for instance at a temperature of from 160 to 190° C., or at a temperature of from 170 to 180° C. This typically results in the formation of a dark solution.

Typically, step (a2) comprises heating the resulting solution to dryness. The temperature at which the solution is heated to dryness can be any suitable drying temperature, but is usually from 200 to 300° C., for instance about 250° C. The resulting solid is typically ground before it is heated again in step (a3).

Usually, step (a3) comprises heating the resulting solid at a temperature of from 300 to 500° C. For instance, the solid may be heated at a first temperature of from 300 to 400° C. and subsequently at a second temperature of about 350 to 500° C.

The zinc citrate solution used in step (a1) may be produced by treating a citric acid solution with zinc oxide. Typically, the resulting mixture is heated, for instance to a temperature of from 50 to 90° C., e.g. to about 70° C. Usually a small amount of a mineral acid, typically nitric acid, is added to the reaction mixture.

The silicon tetra-acetate solution is typically produced by dissolving silicon tetra-acetate in hot ethylene glycol.

In the process of the invention for producing a transparent conducting film by PLD, any suitable substrate can be used. Typically, the substrate is glass, for instance borosilicate glass. However, alternative suitable substrates include sapphire, silicon carbide, alumina (Al₂O₃), zinc oxide (ZnO), yttrium-stabilised zirconium (YSZ), zirconium oxide (ZrO₂), any transparent oxide single crystal, fused silica, quartz and transparent polymer substrates. The transparent polymer may, for instance, be polyethylene terephthalate (PET), poly(methyl methacrylate) (PMMA), polyethylenenaphthalate (PEN) or polycarbonate (PC).

Before the ablation and deposition steps (c) and (d) are performed, the chamber is typically evacuated. Usually, the pressure in the chamber is reduced to less than 1×10⁻⁵ Torr, for instance to about 5×10⁻⁶ Ton. After evacuation, the chamber is then backfilled with a gas which comprises oxygen. Typically, the chamber is backfilled such that the partial pressure of oxygen in the chamber is from about 2 mTorr to about 5 mTorr. The gas with which the chamber is backfilled may be oxygen or a mixture of oxygen with an inert gas, for instance a mixture of oxygen and argon.

Any suitable pulsed laser source may be used. In one embodiment, the laser is a excimer laser, more typically a KrF excimer laser. Laser ablation occurs when the laser beam is focused on the target surface. Typically, during PLD growth, the laser focal spot is fixed while the disk-shaped target is rotated around its surface normal axis and laterally translated back and forth along its surface. This is equivalent to scanning the laser beam across the target surface. Usually, absorption of laser radiation by the target produces, sequentially, melting, vaporization, ejection and plasma (plume) formation.

The wavelength, frequency and power of the pulsed laser beam can depend on, for instance, the specific target material and substrate being used, the atmosphere in the chamber and the particular application of the thin film being formed.

Typically, the laser has a wavelength of from 120 nm to 337 nm. More typically, the wavelength of the laser is 248 nm.

Typically, the laser has an energy per pulse of from 200 mJ to 400 mJ.

Typically, the laser repetition frequency in step (c) of the process is from about 1 Hz to about 100 Hz. More typically, the laser repetition frequency is about 10 Hz.

The pulse duration of each pulse of the pulsed laser beam is typically from about 1 ns to about 100 ns. More typically, the pulse duration is about 10 ns.

The substrate is usually mounted on a substrate heater which can heat the substrate during the deposition process. Typically, during steps (c) and (d) of the process, the substrate is held at a temperature of from 50° C. to 800° C. More typically, the substrate is held at about 350° C.

Typically, the target and the substrate are moveable within the chamber, and can be moved, for instance translated or rotated, during the deposition process.

Accordingly, the substrate is typically mounted on a manipulator which provides for lateral and rotational movement to the substrate in its surface plane. Because the substrate can be laterally translated in the x-y plane, this setup provides a solution to scale up PLD for large area thin film deposition.

The distance between the substrate and the target may also be adjusted using the substrate manipulator.

When the substrate is away from the target, relatively large area thin films can be grown, using the wide angular distribution of the ablation plume further away from its root.

When the substrate is very close to the target, due to the small substrate-target distance and the narrow angular distribution of the ablation plume at its root, small features can be grown on the substrate with sizes similar to the laser focal spot (for instance, from a few microns to submicron diameter). Thus, one purpose of bringing the substrate close to the target is to obtain small deposition features. Furthermore, by laterally translating the substrate, patterned structures (e.g., periodic lines, grids, and dots) can be grown.

Patterned structures can also be grown by masking the substrate.

Usually, during steps (c) and (d) of the process of the invention, the substrate is held at a fixed distance of from about 10 mm to about 100 mm from the target. More typically, the distance between the substrate and target is 73 mm.

By alternating targets of different materials, multilayers of thin films can be grown.

Accordingly, in one embodiment of the process of the invention, the process further comprises (i) providing one or more further target materials in the chamber, which one or more further target materials are different from the target material which comprises zinc oxide and [M], and (ii) growing a multilayer film on said substrate by alternatively using the different target materials.

Typically each target material is placed in a separate target holder, each of the target holders being present in a carousel. In this way, multi-layer thin films can be deposited by rotating the carousel and thereby alternating the target material.

In one embodiment, the film of the invention comprises a plurality of layers.

The formation of multiple-layer films in this way can be useful for forming different layers of an electrochemical device, for instance a photovoltaic device or an electroluminescent device.

With the above-mentioned capability of precise deposition of micron-scale features using the process of the invention, two-dimensionally patterned structures such as arrays of dots and lines can be obtained simply by positioning the substrate close to the target and translating the substrate laterally. This process can thus serve as a means of “direct writing” of the films of the present invention. The term “direct writing” describes a range of technologies which can fabricate two or three dimensional functional structures, in situ, directly onto flat or conformal surfaces in complex shapes. This can be on a micro scale or nano scale. Direct writing can address potentially difficult substrate materials, demands of high precision forms, reconfigurable designs and direct fabrication of a robust finished product. There are diverse benefits for business from direct writing technology. From rapid and cost-effective prototyping to novel functionality, it is expected to deliver major advantages to business in the long term. The PLD process of the present invention can be used to produce complex patterned transparent conducting films by direct writing.

Accordingly, in one embodiment step (d) of the process further comprises forming a patterned structure, usually a two-dimensionally patterned structure, on the substrate by positioning the substrate close to the target material and laterally translating the substrate during deposition.

In another embodiment the process of the invention further comprises: (i) positioning the substrate at a first distance from the target material, and allowing the plasma to be deposited on the substrate to form a large area film; and (ii) positioning the substrate at a second distance from the target material, which second distance is shorter than the first distance, and allowing the plasma to be deposited to form patterned structures on said substrate.

A combination of the two film growth processes, at long and short target-substrate distances, can provide a variety of designed growth patterns. 3D structures can be built up in this way. For instance, by alternating growth processes at long and short substrate-target distances using a different target material at each distance, lateral (in-plane) periodic structures can be obtained and then covered with intermediate layers of different materials.

Accordingly, in one embodiment, the process further comprises forming a three-dimensionally patterned structure on the substrate. Typically, this embodiment comprises depositing combinations of (i) arrays of dots and/or lines, and (ii) thin layers, by controlling the distance between the substrate and the target material and by laterally translating the substrate.

Accordingly, in one embodiment, the film of the invention has a patterned structure. The patterned structure may be a two-dimensionally patterned structure or a three-dimensionally patterned structure.

Patterned structures may also be formed using other patterning techniques, for instance by etching the film or by lithography, screen printing or ink jet printing. In this way, the resulting film can have any desired two-dimensional or three-dimensional pattern.

A patterned film structure is useful in many applications, including in the design of printed electrodes or circuit boards, for instance, where the transparent conductive film is only desired in certain specific places.

In order that the transparent conductive film is deposited on only a portion of the substrate, the substrate surface may be masked before depositing the film on the substrate. In this way the film is only formed on the unmasked areas of the substrate, and does not form on the masked areas. Additionally or alternatively, patterning techniques such as ink jet printing, screen printing, direct writing or lithography can be applied to control exactly on which parts of the surface the film is formed. For example, by direct-writing or ink jet printing onto the surface of the substrate in certain places only, film formation occurs only at those places. The resulting film will then have a specific two-dimensional pattern.

Accordingly, in one embodiment of the process of the invention, the film is deposited on only a portion of the surface of the substrate to form a patterned film. Typically, this is achieved by using a patterning technique (for instance by direct writing) or by masking one or more portions of the substrate prior to film formation.

Advantageously, ZnO is an etchable material, so etching can also be used to pattern the transparent conducting films of the invention.

Accordingly, in another embodiment of the process of the invention, the process further comprises subjecting the film to an etching process, thereby producing a patterned film. Any suitable etchant can be used, for instance HBr, HCl, HF and HF/NH₄. In one embodiment, the etchant is an HBr, HCl, HF or HF/NH₄ etch bath.

Such patterning and etching techniques can be performed more than once and/or in combination with one another, leading to the build-up of a complex two- or three-dimensional film pattern.

The transparent conducting films of the invention have electrical and optical properties which are comparable to those of ITO. Furthermore, the films are non-toxic and produced from precursors which are cheaper and more abundant than indium metal. The films therefore represent an attractive alternative to ITO, and can in principle be used instead of ITO in any of the transparent conductor applications of ITO. Since the cost of making ZnO is very low, ZnO is particularly attractive for large scale applications such as solid-state lighting, transparent electronics, flat-panel displays and solar cells (particularly large-area solar cells).

By virtue of its electrical and optical properties, the doped zinc oxide film of the invention is particularly suitable for use as a transparent conducting coating in many of the applications for which ITO is useful. For instance, film of the invention may be used as an antistatic coating, an optical coating, a heat-reflecting coating, an antireflection coating, an electromagnetic interference shield, a radio-frequency interference shield, an electrowetting coating, or a coating for a display, touch panel or sensor. A heat-reflecting coating comprising a doped zinc oxide film of the invention is particularly useful as a coating for a window, for instance an architectural or automotive window. Such heat-reflecting coatings may also be used in vapour lamp glasses.

Accordingly, the invention further provides a transparent conducting coating which comprises a transparent conducting film of the invention.

Accordingly, the invention also provides glass which is coated with a transparent conducting coating of the invention.

The transparent conducting coatings and films of the invention can also be used in electronic devices, for instance in organic light-emitting devices, electroluminescent devices, photovoltaic devices, solar cells and photodiodes. They can also be used in electrodes and in displays, for instance in liquid crystal displays, electroluminescent displays, electrochromic displays, flat panel displays, plasma displays, electronic paper and field emission displays. Additionally, the coatings and films may be usefully employed in touch panels, sensors, flooring material (for instance to provide antistatic flooring), minors, lenses, Bragg reflectors, strain gauges or a radio-frequency identification (RFID) tags.

Accordingly, the invention further provides an electronic device; an electrode, a display, a touch panel, a sensor, a window, a floor material, a minor, a lense, a Bragg reflector, a strain gauge or a radio-frequency identification (RFID) tag which comprises a transparent conducting coating of the invention or a transparent conducting film of the invention.

The invention additionally provides a substrate which is coated with a transparent conducting coating of the invention. Typically, the substrate is a polymer or glass. Typically, the polymer is flexible. The polymer may be any suitable polymer and is typically a conjugated polymer, for instance PET (polyethylene terephthalate). Such coated polymers are useful in flexible electronics applications.

The present invention is further illustrated in the Examples which follow:

EXAMPLES Example 1 Synthesis of Doped Zinc Oxide Thin Films

This Example details the synthesis of doped zinc oxide thin films of the invention with electrical and optical properties that are comparable to ITO. In this Example, silicon is used as the dopant element [M]. These materials are attractive for transparent electrode applications as they are easy to grow from very cheap and abundant, precursors and are non-toxic.

1. Experimental Procedure 1.1 Pulsed Laser Deposition System

FIG. 1 shows a schematic diagram of the PLD apparatus. The stainless steel vacuum chamber was evacuated by the turbo molecular pump to the base pressure at approximately 10⁻⁷ ton.

There are six target holders and one substrate holder in the chamber. The six target holders are on the carrousel. In this way, multilayer thin films can be deposited by rotating the target carrousel.

A KrF excimer laser (Lambda physics LPX 300) with a wavelength of 248 nm was used for ablation of a pure ZnO target and Si-doped ZnO targets (i.e. targets containing 0-5 wt % of SiO₂, corresponding to about 0-6.7 atom % Si). A laser repetition frequency of 10 Hz was used at an energy of 250-400 mJ per pulse, for 5000 pulses. Absorption of laser radiation by the target produces, sequentially, melting, vaporization, ejection and plasma formation. The ablated plasma was deposited on borosilicate glass substrates held 73 mm from the target, held at a temperature of 350° C. The deposition chamber was initially evacuated to 5×10⁻⁶ Ton, and then backfilled with pure oxygen gas to 2-5 mTorr before deposition.

1.2 Sample Preparation

Silicon doped ZnO (SZO) targets were prepared from Zinc oxide (purity, 99.99%) and SiO₂ (purity 99.99%) powders. 0-5 wt % SiO₂ was used, corresponding to 0-6.655 atom % Si. The powders were mixed in acetone and then fired at 800° C. for 12 hrs in air, ground, and fired again at 800° C. for a further 7 hrs in air. The solubility limit of SiO₂ in ZnO and the phase purity of SiO₂—ZnO were determined by X-ray powder diffraction (Philips X′Pert diffractometer). Disk-shaped targets, 25 mm in diameter and 2 mm thick were prepared from the sintered powders by standard pellet press (10-14 ton), and then sintered at 800° C. for 7 hrs in air to lend mechanical strength to the target.

The borosilicate glass substrates were cleaned in an ultrasonic cleaner for 15 min with acetone, ethanol and then dried with filtered air before being introduced into the deposition system. Ablation was performed with the laser operating at a repetition frequency of 10 Hz, and energy of 250-400 mJ per pulse for a duration of 5000 pulses.

1.3 Characterisation of Films

The crystalline structure of thin film was studied by X-ray diffractometer (Philips X′Pert diffractometer). The thickness (d) of the films was measured using a surface profilometer (Dektak 3) after etching the film by HBr acid. The film resistivity ρ, conductivity σ, carrier concentration η, and Hall mobility μ were determined from the sheet resistance measurement by a four-point probe Hall measurement system (HMS 3000). The elemental compositions of the films were determined by energy dispersive spectroscopy. Surface morphology of the films was studied using atomic force microscopy (AFM) using a Nanoscope III microscope. The transparencies of the films were also determined. Transparency can be measured using any suitable method. Convenient methods for measuring transparency, including spectroscopic methods, are well known in the art. Transparency can, for instance, be determined by measuring the transmittance of visible light through the sample film and comparing that with the transmittance of visible light through a “standard” or “reference” film (which may, for instance, be a glass film).

2. Results 2.1 Electrical Properties

The electrical properties of Si doped ZnO (SZnO) films depend on both the film composition and the deposition parameters. FIG. 2 shows the typical variation of film resistivity (ρ) and carrier concentration (η) as a function of the SiO₂ content in the SZnO targets. The films were deposited at 350° C. and the oxygen was 5 mTorr.

Table 1 shows that the resistivity of the SZnO films was observed to initially decrease with increasing SiO₂ content, with maximum conductivity and carrier concentration obtained for 2 wt % SiO₂ (which corresponds to about 2.7 atom % silicon in the SZnO film; a molar ratio of Zn to Si of (1-x):x where x is 0.027).

As a small amount of silicon is introduced into the film, it is ionized to Si⁺⁴, nominally replacing Zn⁺², with two electrons produced for each zinc atom replacement. The electron density (carrier concentration) of the samples should, therefore, increase linearly with increasing silicon content. Indeed, an initial, linear, increase in carrier concentration is observed and results in a decrease in the resistivity of the film. The resistivity of the films reaches a minimum at 2 wt % of SiO₂ (2.7 atom % Si), and thereafter gradually increases with increasing Si content.

It is thought that the decrease in carrier concentration and increase in resistivity beyond 2 wt % of SiO₂ content (2.7 atom % Si) is due to increased disorder of the crystal lattice, which causes phonon scattering and ionized impurity scattering and results in a decrease in mobility. It has also been suggested that for films with higher doping levels, the increase in disorder acts to decreases the mobility and free carrier concentration. Alternatively, the increase in resistivity with increasing Si content beyond 2 wt % (2.7 atom %) may be due to the dopant atoms forming neutral defects, which do not contribute free electrons, or to an increase in the concentration of the electron traps as a result of excess Si doping.

TABLE 1 A comparison of resistivity, Hall mobility, carrier concentration, conductivity and transparency for Si doped ZnO films (at different weight percentages of SiO₂) with indium tin oxide films (5% Sn), grown on glass substrate at 350° C. and in 5 mTorr of oxygen. Carrier Conduct- Mobility (μ) Concentration ivity (σ) Resistivity Thickness Sample cm²/Vs (η) cm⁻³ Ω cm (p) Ω cm Transparency nm ZnO 1.45 × 10⁺¹ 4.09 × 10⁺¹⁹ 9.54 × 10⁺¹ 1.04 × 10⁻² 86.87% 263 1% Si-ZnO 1.47 × 10⁺¹  1.2 × 10⁺²⁰ 2.86 × 10⁺² 3.49 × 10⁻³  80.8% 277 2% Si-ZnO  2.6 × 10⁺¹ 6.04 × 10⁺²⁰ 2.55 × 10⁺³  3.9 × 10⁻⁴  81.5% 255 3% Si-ZnO 1.85 × 10⁺¹ 3.66 × 10⁺²⁰ 1.67 × 10⁺³  5.9 × 10⁻⁴  84.6% 258 5% Si-ZnO  1.6 × 10⁺¹ 2.62 × 10⁺²⁰  6.7 × 10⁺² 1.47 × 10⁻³ 83.92% 270 ITO PLD  3.2 × 10⁺¹ 6.45 × 10⁺²⁰ 3.89 × 10⁺³ 2.57 × 10⁻⁴  83.2% 260 ITO 3.58 × 10⁺¹ 2.19 × 10⁺²⁰ 1.26 × l0⁺³ 7.94 × 10⁻⁴ 150 standard ITO 3.66 × 10⁺¹ 6.68 × 10⁺²⁰ 4.03 × 10⁺³ 2.47 × 10⁻⁴ 175 commercial

2.2 Structural Properties

The crystalline structure of the films was studied by XRD (Cukα, λ=1.5406 A°). FIG. 3 shows the X-ray diffraction patterns for undoped ZnO and Si-doped ZnO films grown at 350° C. in 2-5 mTorr of oxygen. Si-doped ZnO films were always observed to be polycrystalline and showed a similar crystal structure to that of undoped ZnO. Only two diffraction peaks of (002) and (004) orientation can be observed and this result indicates that the Si:ZnO films were strongly oriented with the c axis perpendicular to the quartz substrate plane. The 2 wt % SiO₂ (2.7 atom % Si) doped ZnO thin film had the highest (002) diffraction peak intensity. Moreover, the peak intensities of those films decreased with increased doping concentration more than 2 wt %. The (002) diffraction peak intensity had a tendency to decrease with an increase in doping concentration in films. This indicates that an increase in doping concentration deteriorates the crystallinity of films, which may be due to the formation of stresses by the difference in ion size between zinc and the dopant and the segregation of dopants in grain boundaries for high doping concentration. The XRD spectra peak locations are slightly shifted with respect to those of pure ZnO as can be seen in FIGS. 3 and 4. The XRD spectrum shows no similarities to the expected powder pattern peak intensities, which would suggest that the films are textured.

2.3 Surface Morphology

FIGS. 5 and 6 show 2-D atomic force microscopy (AFM) images (2 μm×2 μm) of the undoped (FIG. 6) and Si-doped (FIG. 5) films deposited by PLD technique on borosilicate substrate. As in these images the grain growth in the direction perpendicular to the substrate surface. The root-mean-square (RMS) surface roughness value of the Si-doped film was 2.62 nm, compared to a value of 3.2 nm for the undoped ZnO.

Example 2 Low-Temperature Preparation of a Single Phase of Nanopowder of 5 Wt % and 10 wt % of SiO₂—ZnO

Zinc citrate solution was prepared by adding zinc oxide into a citric acid solution with a 1:2 molar ratio of metal ions to citric acid. The solution was heated up to 70° C., and 5 ml of 65% HNO₃ added with stirring. Stirring was continued for 2 hrs. The appropriate ratio of silicon tetra-acetate was dissolved in hot ethylene glycol and the solution was then heated up to 110° C. The temperature of zinc citrate solution was increased to 90° C. with stirring and the silicon acetate solution in ethylene glycol added, with the temperature maintained for 2 hrs. The temperature of the mixture was then increased to 130° C. and a pale yellow clear solution obtained. The temperature for was maintained for 14 hrs, and then increased to 170-180° C., at which point the solution converts to a dark brown thick solution. The solution was heated to dryness at 250° C. for 7 hrs, and the resultant powder was ground and then heated again at 350° C. for 7 hrs and then finally at 400° C. XRD shows single phase with good crystallinity (FIGS. 7 and 8). 

1. A transparent conducting film which comprises a compound of formula (I): Zn_(1-x)[M]_(x)O_(1-y)[X]_(y)  (I) wherein: x is greater than 0 and less than or equal to 0.25; y is from 0 to 0.1; [X] is at least one dopant element which is a halogen; and [M] is: (a) a dopant element which is selected from: a group 14 element other than carbon; a lanthanide element which has an oxidation state of +4; and a transition metal which has an oxidation state of +4 and which is other than Ti or Zr; or (b) a combination of two or more different dopant elements, at least one of which is selected from: a group 14 element other than carbon; a lanthanide element which has an oxidation state of +4; and a transition metal which has an oxidation state of +4 and which is other than Ti or Zr.
 2. A transparent conducting film according to claim 1 wherein when [M] is a combination of two or more different dopant elements, none of said elements is Ga.
 3. A transparent conducting film according to claim 1 which does not contain Ga.
 4. A transparent conducting film according to claim 1 wherein [M] is Si.
 5. A transparent conducting film according to claim 1 wherein x is from 0.01 to 0.05.
 6. A transparent conducting film according to claim 1 wherein [X] is F and y is greater than 0 and less than or equal to 0.1.
 7. A transparent conducting film according to claim 1 wherein y is
 0. 8. A transparent conducting film according to claim 1, which film has a resistivity, p, of less than or equal to about 4.0×10⁻³ Ωcm.
 9. A transparent conducting film according to claim 1, which film has a resistivity, ρ, of less than or equal to about 8.0×10⁻⁴ Ωcm.
 10. A transparent conducting film according to claim 1 which has a mean optical transparency in the visible range of the spectrum of greater than or equal to about 75%.
 11. A transparent conducting film according to claim 1 which has a two- or three-dimensionally patterned structure.
 12. A transparent conducting film according to claim 1 which comprises two or more different layers.
 13. A process for producing a transparent conducting film, which film comprises a compound of formula (I): Zn_(1-x)[M]_(x)O_(1-y)[X]_(y)  (I) wherein: x is greater than 0 and less than or equal to 0.25; y is from 0 to 0.1; [X] is at least one dopant element which is a halogen; and [M] is: (a) a dopant element which is selected from: a group 14 element other than carbon; a lanthanide element which has an oxidation state of +4; and a transition metal which has an oxidation state of +4 and which is other than Ti or Zr; or (b) a combination of two or more different dopant elements, at least one of which is selected from: a group 14 element other than carbon; a lanthanide element which has an oxidation state of +4; and a transition metal which has an oxidation state of +4 and which is other than Ti or Zr; which process comprises producing said film by pulsed laser deposition.
 14. A process according to claim 13 which comprises: (a) providing a target material in a chamber, which target material comprises the elements Zn, O, [M] and optionally [X] wherein [M] and [X] are as defined in claim 10; (b) providing a substrate in the chamber; (c) focusing a pulsed laser beam on the target material to generate a plasma; and (d) depositing the plasma on the substrate to form the film.
 15. A process according to claim 14 wherein the target material is produced by heating a mixture of zinc oxide and an oxide of [M].
 16. A process according to claim 15 wherein the mixture of zinc oxide and an oxide of [M] is heated at a temperature of from about 600° C. to about 1000° C.
 17. A process according to claim 14 wherein the target material is produced by: (a1) heating a solution comprising a zinc compound and a compound comprising [M]; (a2) performing a solvent removal step; and (a3) heating the resulting solid to produce said target material.
 18. A process according to claim 17 wherein the temperature of said heating in step (a1) does not exceed 200° C. and wherein the temperature of said heating in step (a3) does not exceed 500° C.
 19. A process according to claim 17 wherein said zinc compound is zinc citrate and said compound comprising [M] is silicon tetra-acetate.
 20. A process according to claim 14 wherein the process further comprises (i) providing one or more further target materials in the chamber, which one or more further target materials are different from said target material which comprises Zn, O, [M] and optionally [X], and (ii) growing a multilayer film on said substrate by alternatively using the different target materials.
 21. A process according to claim 14 wherein step (d) of the process further comprises forming a two- or three-dimensionally patterned structure on the substrate.
 22. A process according to claim 14 wherein the plasma is deposited on only a portion of the surface of the substrate, in order to form a patterned film.
 23. A process according to claim 13 wherein the process further comprises subjecting the film to etching, thereby producing a patterned film.
 24. A transparent conducting film obtainable by a process as defined in claim
 13. 25. A transparent conducting coating which comprises a transparent conducting film as defined in claim
 1. 26. A transparent conducting coating according to claim 25 which is an antistatic coating, an optical coating, a heat-reflecting coating, an antireflection coating, an electromagnetic interference shield, a radio-frequency interference shield, an electrowetting coating, or a coating for a display, for a touch panel or for a sensor.
 27. An organic light-emitting device, an electroluminescent device, a solid-state light, a photovoltaic device, a solar cell, a photodiode, a transparent electronic device, an electrode, a display, a touch panel, a sensor, a window, flooring material, a minor, a lens, a Bragg reflector, a strain gauge or a radio-frequency identification (RFID) tag which comprises a transparent conducting coating as defined in claim 25 or a transparent conducting film as defined in claim
 1. 28. A display as defined in claim 27 which is a liquid crystal display, an electroluminescent display, an electrochrome display, a flat panel display, a plasma display, electronic paper or a field emission display.
 29. A polymer or glass which is coated with a transparent conducting coating as defined in claim
 25. 30. A transparent conducting film according to claim 3 wherein [M] is Si.
 31. A process according to claim 18 wherein said zinc compound is zinc citrate and said compound comprising [M] is silicon tetra-acetate. 